TW202233498A - Transport cart system - Google Patents

Abstract

This transport cart system comprises a transport cart that travels along a track, a control device that controls the transport cart, and power supply devices that are provided in each of a plurality of sections formed by dividing the track. Each of a plurality of the power supply devices has a monitor device that monitors the state of the power supply device, and a communication device that transmits the monitoring results by the monitor device to the control device. The control device controls the transport cart according to the monitoring results.

Description

Handling trolley system

One aspect of the present invention pertains to a handling dolly system.

As a conveyance cart system, a system including a conveyance cart that travels along a rail and a control device that controls the conveyance cart is known (for example, refer to Patent Document 1). [Prior Art Literature] [Patent Literature]

Patent Document 1: Japanese Patent Laid-Open No. 2013-35670

[Problems to be Solved by Invention]

In the above-described technology, for example, when a malfunction occurs in the power supply device of the system, there is a possibility that the entire system is shut down (in a state of abnormal operation) the system shuts down.

Therefore, one aspect of the present invention is to provide a transport trolley system that can prevent the system from being shut down. [Technical means to solve problems]

A transport trolley system according to one aspect of the present invention includes: a transport trolley that travels along a rail; a control device that controls the transport trolley; Each of the devices includes a monitoring device that monitors the state of the power supply device, and a communication device that transmits a monitoring result generated by the monitoring device to a control device, and the control device controls the transport trolley based on the monitoring result.

In this conveyance cart system, the power supply device is installed in each of the plurality of sections, the state of each power supply device is monitored by the monitoring device, and the conveyance cart is controlled by the control device according to the monitoring result. Thereby, when a failure occurs in the power supply device, it is possible to execute a process that is not a shutdown of the entire system but a local shutdown by the control device. Therefore, it is possible to prevent the system shutdown of the transport trolley system.

In the transport cart system according to one aspect of the present invention, the control device may determine whether or not the states of the plurality of power supply devices are abnormal based on the monitoring result, and prohibit the transport cart from entering a section corresponding to the power supply device determined to be in the abnormal state. , and the conveyance trolley existing in the section is withdrawn from the section. In this way, it is possible to effectively suppress the situation that the bad influence caused by the failure of the power supply device spreads to the whole system.

In the transport cart system according to one aspect of the present invention, the control device may be a device that further controls the power supply device, and may stop the power supply device determined to be in an abnormal state. In this way, it is possible to effectively suppress the situation that the bad influence caused by the failure of the power supply device spreads to the whole system.

In the transport trolley system according to one aspect of the present invention, the control device may determine, based on the monitoring result, whether the states of the plurality of power supply devices are in a warning state with a degree of abnormality lower than the abnormal state, and determine whether the state of the plurality of power supply devices is a warning state. The acceleration of the transport trolley in the section corresponding to the power supply device in the warning state is limited. In this way, it is possible to effectively suppress the situation that the bad influence caused by the failure of the power supply device spreads to the whole system.

In the transport trolley system according to one aspect of the present invention, when the control device determines that the state of the power supply device is an abnormal state, and when the abnormal state is a temperature abnormality, the communication device may send a message to the control device. Information on the temperature distribution in the power supply device determined to be in an abnormal state. Thereby, the user can easily grasp the temperature distribution in the power supply device that causes the temperature abnormality in the control device.

In the transport trolley system according to one aspect of the present invention, the monitoring result may include: first information including at least one of temperature data and power data of the power supply device; and second information about the state of the power supply device Whether it is in an abnormal state, the first information is sent from the communication device to the control device in the first cycle, and the second information is sent from the communication device to the control device in the second cycle shorter than the first cycle when the power supply device is normal . Accordingly, when the first information and the second information are periodically transmitted from the power supply device to the control device, the communication cycle of the first information having a larger data capacity than that of the second information is longer than the communication cycle of the second information. Therefore, the traffic of the communication device can be suppressed. [Inventive effect]

According to one aspect of the present invention, it is possible to provide a transport trolley system that can prevent the system from being shut down.

Hereinafter, one embodiment will be described in detail with reference to the drawings. In addition, in description of drawings, the same code|symbol is attached|subjected to the same or equivalent element, and the repeated description is abbreviate|omitted. The words "up" and "down" correspond to the vertical direction, the words "front" and "rear" correspond to the traveling direction of the carriage, and the words "left" and "right" correspond to the directions orthogonal to the vertical direction and the front-rear direction. .

As shown in FIGS. 1 and 2 , the transport cart system 1 is, for example, a system in which an article 10 is transported between a plurality of placement units 9 using a transport cart 6 in a factory or the like. The conveyance cart system 1 includes: a conveyance cart 6 that travels along a rail 4 ; a plurality of placing parts 9 that place articles 10 ; a control device 5 that controls the conveyance cart 6 ; and a power supply device 8 that supplies power to the conveyance cart 6 . The article 10 includes, for example, a container such as a FOUP (Front Opening Unified Pod) for storing a plurality of semiconductor wafers, a grating box for storing a glass substrate, and general parts.

The rail 4 is, for example, a rail installed in the vicinity of the ceiling in the head space of the operator. The track 4 is suspended from the ceiling. The rail 4 is a predetermined traveling path for causing the conveyance cart 6 to travel. Track 4, distinguished by a complex numbered interval. In the example shown in the figure, the track 4 is divided into the first section 4X and the second section 4Y.

Rails 4 are supported by struts 40A. The rail 4 has a rail body 40, a C-shaped cross section formed by a pair of bottom surface portion 40B, a pair of side surface portions 40C, and a top surface portion 40D, a power feeding portion 40E, and a magnetic plate 40F. The bottom surface portion 40B extends in the traveling direction of the transport vehicle 6 and constitutes the bottom surface of the rail main body portion 40 . The bottom surface portion 40B is a plate-like member on which the running rollers 51 of the transport trolley 6 roll and run. The side surface portion 40C extends in the traveling direction of the transport vehicle 6 , and constitutes the side surface of the rail body 40 . The top surface portion 40D extends in the traveling direction of the conveyance trolley 6 and constitutes the upper side surface of the rail body 40 .

The power supply unit 40E is a part that supplies electric power to the power receiving core 57 of the conveyance cart 6 and transmits and receives signals with the conveyance cart 6 . The power feeding portion 40E is a power feeding wire that is respectively fixed to the pair of side surface portions 40C and that extends along the extending direction of the rail 4 . The power supply unit 40E supplies power without contacting the power receiving core 57 . The power supply unit 40E is provided in each of the plural sections of the rail 4 . The feeding portion 40E includes a first feeding portion 40EX extending along the rail 4 of the first section 4X, and a second feeding section 40EY extending along the rail 4 of the second section 4Y.

The magnetic plate 40F generates a magnetic force for running or stopping in the LDM (Linear DC Motor) 59 of the conveyance trolley 6 . The magnetic plate 40F is fixed to the top surface portion 40D and extends in the running direction. In addition, the length, shape, and layout of the rails 4 are not limited to the example shown in the drawings, and various lengths, shapes, and layouts may be used.

The transport trolley 6 travels along the rail 4 and transports the articles 10 . The transport trolley 6 is configured to be able to transfer the article 10 . The transport trolley 6 is an overhead traveling type unmanned traveling vehicle. The number of overhead transport vehicles 6 included in the transport truck system 1 is not particularly limited, and may be one or plural. The transport trolley 6 is also called eg a trolley, an overhead travel vehicle, an overhead transport vehicle, or a traveling trolley. The transport cart 6 includes a main body portion 7 , a traveling portion 50 , and a traveling cart controller 35 . The body portion 7 includes a body frame 22 , a traverse portion 24 , a θ drive portion 26 , a lift drive portion 28 , a lift table 30 , and front and rear frames 33 .

The traverse unit 24 traverses the θ drive unit 26 , the lift drive unit 28 , and the lift table 30 together in a direction at right angles to the running direction of the rail 4 . The θ drive unit 26 rotates at least one of the lift drive unit 28 and the lift table 30 within a predetermined angle range within a horizontal plane. The raising/lowering drive part 28 raises and lowers the raising/lowering table 30 by twisting or feeding out suspension members such as belts, wires, and ropes. The chuck is provided on the lift table 30, and the article 10 can be freely held or released. A pair of front and rear frames 33 are provided, for example, in the front and rear of the traveling direction of the transport vehicle 6 . The front and rear frames 33 are protruded and retracted with claws, etc., not shown, in order to prevent the articles 10 from falling off during conveyance.

The traveling part 50 makes the conveyance trolley 6 travel along the rail 4 . The traveling portion 50 includes a traveling roller 51 , a side roller 52 , a power receiving core 57 , and an LDM 59 . The running rollers 51 are arranged at the front and rear left and right ends of the running part 50 . The running rollers 51 roll on the pair of bottom surface portions 40B of the rails 4 . The side rollers 52 are arranged to sandwich the running rollers 51 in the front-rear direction. The side rollers 52 are provided so as to be in contact with the side surfaces 40C of the rail 4 . The power receiving cores 57 are arranged in the front and rear of the traveling part 50 so as to interpose the LDM 59 in the left-right direction. The power receiving core 57 performs power reception by non-contact from the power supply unit 40E arranged on the rail 4 and transmission and reception of various signals by non-contact with the carriage controller 35 . The LDM 59 is provided in the front and rear of the running part 50 . The LDM59 generates a magnetic force for walking or stopping.

The traveling vehicle controller 35 is an electronic control unit including a CPU (Central Processing Unit), a ROM (Read Only Memory), a RAM (Random Access Memory), and the like. The carriage controller 35 controls various operations of the transport cart 6 . Specifically, the traveling vehicle controller 35 controls the traveling unit 50 , the traverse unit 24 , the θ drive unit 26 , the lift drive unit 28 , and the lift table 30 . The traveling vehicle controller 35 can be configured as software executed by a CPU, for example, a program stored in a ROM is read into the RAM. The traveling vehicle controller 35 may be configured as a hardware formed of an electronic circuit or the like. The traveling vehicle controller 35 communicates with the control device 5 using the power supply unit 40E and the like.

The placement portion 9 is arranged along the rail 4 . The placing portion 9 is provided at a position where the articles 10 can be delivered by the conveyance trolley 6 . The placing portion 9 includes a temporary storage area for placing the articles 10 temporarily, and a loading port for assigning the articles 10 to a processing device (not shown).

The control device 5 is an electronic control unit composed of a CPU, a ROM, a RAM, and the like. The control device 5 can be configured as software executed by a CPU, for example, a program stored in a ROM is read into the RAM. The control device 5 may be configured as a hardware formed of an electronic circuit or the like. The control device 5 controls various operations of the transport cart system 1 . The control device 5 controls the conveyance cart 6 and the power supply device 8 . The control device 5 includes a display unit 5A that displays various kinds of information on a monitor, etc.; an input unit 5B that accepts various operation inputs from a user, such as a keyboard, a mouse, and the like; and a memory unit 5C that stores various kinds of information.

The control device 5 is connected to the communication device 3 . The communication device 3 is a device that communicates with the power supply device 8 . The communication device 3 outputs various information received from the power supply device 8 to the control device 5 . The communication device 3 transmits various information input from the control device 5 to the power supply device 8 . The communication device 3 is not particularly limited, and for example, a known communication converter can be used.

The control device 5 transmits a request for temperature and power information (first information) related to the temperature data and power data of the power supply devices 8 to the plurality of power supply devices 8 via the communication device 3 . The control device 5 obtains the temperature and power information sent from the power supply device 8 according to the request via the communication device 3 . The control device 5 sends a request to the plurality of power supply devices 8 via the communication device 3 to transmit device status information (second information) that the state of the power supply devices 8 is an abnormal state, a warning state, or a normal state. The control device 5 obtains the device status information sent from the power supply device 8 according to the request via the communication device 3 . The control device 5 stores the acquired temperature power information and device state information in the memory unit 5C.

The power supply device 8 is provided in each of the plural sections of the rail 4 . Here, the power feeding device 8 includes a power feeding device 8X provided corresponding to the first section 4X of the rail 4 , and a power feeding device 8Y provided corresponding to the second section 4Y of the rail 4 . The power feeding device 8X is connected to the first power feeding unit 40EX of the first section 4X. The power feeding device 8Y is connected to the second power feeding unit 40EY in the second section 4Y.

As shown in FIG. 3 , the power supply device 8 includes a plurality of non-contact temperature sensors 81 , a current sensor 82 , a power supply device control unit 83 , and a communication device 84 . The non-contact temperature sensor 81 is a sensor that monitors the temperature of the power supply device 8 . As the non-contact temperature sensor 81, for example, a thermopile array sensor is used. Each of the plurality of non-contact temperature sensors 81 measures the respective temperatures of the plurality of regions in the power supply device 8 that are different from each other in a non-contact manner. Each non-contact temperature sensor 81 detects the temperature distribution in its area, and outputs information about the temperature distribution to the power supply device control unit 83 as temperature data. For example, in the temperature data, the temperature distribution is associated with each identification number of the non-contact temperature sensor 81 . The current sensor 82 is a sensor that monitors the current at a predetermined measurement point in the power supply device 8 . The current sensor 82 detects the current at a predetermined measurement point, and outputs information about the current to the power supply device control unit 83 as current data.

The power supply device control unit 83 is an electronic control unit including a CPU, a ROM, a RAM, and the like. The power supply device control unit 83 controls various operations in the power supply device 8 . The power supply device control unit 83 can be configured as software executed by the CPU, for example, by reading a program stored in the ROM into the RAM. The power supply device control unit 83 may be constituted as hardware by an electronic circuit or the like.

The power supply device control unit 83 determines whether the power supply device 8 is in any one of an abnormal state, a warning state, and a normal state based on the temperature data and the power data. The warning state is a state with a lower degree of abnormality than the abnormal state. For example, the power supply device control unit 83 takes the state of the power supply device 8 as a warning state when the power data is equal to or greater than the first power threshold value. For example, the power supply device control unit 83 sets the state of the power supply device 8 as an abnormal state when the power data is equal to or more than a second power threshold value larger than the first power threshold value. For example, the power supply device control unit 83 sets the state of the power supply device 8 as a warning state when any one of the maximum temperatures of the temperature distributions in the temperature data is equal to or higher than the first temperature threshold. For example, the power supply device control unit 83 sets the state of the power supply device 8 as an abnormal state (temperature abnormality) when any of the maximum temperatures of the temperature distributions in the temperature data is equal to or higher than the second temperature threshold value, which is larger than the first temperature threshold value. ). In other cases than the above, the power supply device control unit 83 takes the state of the power supply device 8 as the normal state.

The power supply device control unit 83 outputs the result of judging whether the power supply device 8 is in any one of the abnormal state, the warning state and the normal state according to the request from the control device 5 to the communication device 84 as device state information. The data size of the device status information is, for example, 20 to 80 bytes. Device status information may also consist of error records. The power supply device control unit 83 outputs the temperature data and the power data to the communication device 84 as temperature and power information according to the request from the control device 5 . The data size of the temperature and power information is, for example, 80 to 204 bytes.

In addition, the non-contact temperature sensor 81 and the current sensor 82 are configured as monitoring devices for monitoring the state of the power supply device 8 . In addition, the temperature power information and the device state information are constituted as monitoring results of the state of the power supply device 8 obtained by monitoring by the monitoring device (hereinafter, also simply referred to as "monitoring results of the power supply device 8").

The communication device 84 is a device that communicates with the control device 5 via the communication device 3 . The communication device 84 outputs various received information to the power supply device control unit 83 . The communication device 84 transmits various information input from the power supply device control unit 83 to the control device 5 . The communication device 84 transmits the monitoring result of the power supply device 8 to the control device 5 (the details will be described later). The communication device 84 is not particularly limited, and for example, a known communication converter can be used.

In the present embodiment, the control device 5 controls the transport cart 6 based on the monitoring result of the power supply device 8 . The control device 5 determines whether or not the states of the plurality of power supply devices 8 are abnormal based on the monitoring results of the power supply devices 8 . When the control device 5 determines that at least any one of the plurality of power supply devices 8 is in an abnormal state, the control device 5 prohibits the transport cart 6 from entering the section corresponding to the power supply device 8 determined to be in the abnormal state on the rail 4, and makes the conveyance existing in the section. The cart 6 retreats from this section. The control device 5 stops the power supply device 8 determined to be in an abnormal state. The stop of the power supply device 8 includes at least the stop of the power supply to the power supply unit 40E connected to the power supply device 8 .

The control device 5 determines whether or not the states of the plurality of power supply devices 8 are in the warning state based on the monitoring results of the power supply devices 8 . When it is determined that at least one of the plurality of power supply devices 8 is in the warning state, the control device 5 limits the acceleration of the transport vehicle 6 in the section corresponding to the power supply device 8 determined to be in the warning state on the track 4 .

The control device 5 further determines whether or not the abnormal state is a temperature abnormality when at least any one of the plurality of power supply devices 8 is determined to be in an abnormal state. When the control device 5 determines that the abnormal state is an abnormal temperature, the temperature data of the power supply device 8 determined to be in the abnormal state is transmitted from the communication device 84 of the power supply device 8 to the control device 5 . Thereby, in the control apparatus 5, the image of the temperature distribution which becomes a temperature abnormality is produced|generated based on the transmitted temperature data, and this temperature distribution image is displayed on the display part 5A. Details of various flows accompanying the processing of the control device 5 will be described later.

FIG. 4 is a diagram showing a display example displayed on the display unit 5A of the control device 5 . The display example shown in FIG. 4 is an example in which a temperature abnormality occurs in the power supply device 8 of PSP2 among the power supply device 8 with the number PSP1 and the power supply device 8 with the number PSP2. On the display unit 5A, the temperature distribution image G1 related to the temperature distribution of the abnormal temperature in the power supply device 8 of the PSP 2 and the acquisition time thereof are displayed. In addition, on the display unit 5A, various information of the power supply device 8 of the PSP 2 in which the temperature abnormality has occurred is displayed. Various types of information displayed on the display unit 5A include, for example, the number of the power supply device 8 , the status, whether it is in operation, power data, and the maximum temperature for each temperature distribution detected by the non-contact temperature sensors 81 .

In addition, when the user clicks the button "PSP1" by operating the input unit 5B in the display of the display unit 5A as described above, the display can be switched to various information of the power supply device 8 of the PSP1. In addition, in the display of the display unit 5A, for example, when the user clicks the button of "image" by the operation of the input unit 5B, the display can be switched to that of the corresponding non-contact temperature sensor 81. Image data of temperature distribution. In addition, in the display of such a display part 5A, for example, the "temperature bar" of the temperature distribution image G1 can be set by the user operating the input part 5B.

Next, various flows executed in the transport cart system 1 of the present embodiment will be described.

[Regular monitoring process] In the conveyance cart system 1, the next periodic monitoring flow is periodically and repeatedly executed in the first cycle (for example, 10 seconds). In the regular monitoring flow, as shown in FIG. 5( a ), first, the temperature and electric power of all the power supply devices 8 are checked by the control device 5 (step S1 ). In step S1 , specifically, a request for temperature and power information is made from the control device 5 to all the power supply devices 8 via the communication device 3 . Each power supply device 8 receives the request via the communication device 84 and sends the temperature and power information to the communication device 3 according to the request. The control device 5 obtains the temperature and power information through the communication device 3, and stores the obtained temperature and power information in the memory unit 5C.

Next, by the control device 5, the display of the display part 5A is updated so as to facilitate the display of the acquired temperature and power information (step S2). The display aspect and display form of the display unit 5A are not particularly limited, and various aspects and forms may be employed (hereinafter, the same). After that, the process shifts to the above-mentioned step S1 in the next cycle, and the temperature and electric power of all the power supply devices 8 are checked again. In other words, the temperature and power information is sent from the communication device 84 to the control device 5 in the first cycle.

[Manual image acquisition flow] In the transport cart system 1, when the user performs an operation on the input unit 5B to display the temperature distribution image of the temperature distribution detected by the non-contact temperature sensor 81 of a certain power supply device 8 on the display unit 5A, the operation is executed. Next manual image acquisition flow. In the manual image acquisition flow, as shown in FIG. 5( b ), first, the temperature distribution image of the display object is acquired by the control device 5 (step S11 ).

In step S11 , specifically, based on the operation accepted by the input unit 5B, a request for temperature and power information is made from the control device 5 to the target power supply device 8 via the communication device 3 . The object's power supply device 8 receives the request via the communication device 84 and sends the temperature and power information to the communication device 3 according to the request. The control device 5 obtains the temperature power information via the communication device 3, obtains the temperature distribution of the object from the temperature data of the temperature power information, and generates and obtains a temperature distribution image based on the obtained temperature distribution using, for example, a known method.

Next, the display of the display unit 5A is updated by the control device 5 so as to facilitate the display of the acquired temperature distribution image. Further, the acquired temperature distribution image is stored in the memory unit 5C (step S12). With the above, the manual image acquisition flow ends. In addition, the priority of the manual image acquisition flow is set to be lower than that of the above-described periodic monitoring flow. Therefore, when each process of the periodic monitoring flow is being executed, each process of the manual image acquisition flow is not executed.

[Exception monitoring flow] In the conveyance cart system 1, the abnormality monitoring flow described next is repeatedly executed periodically. In the abnormality monitoring flow, as shown in FIG. 6 , first, the device states of all the power supply devices 8 are checked by the control device 5 (step S21 ). In step S21 , specifically, a request for device status information is made from the control device 5 to all the power supply devices 8 via the communication device 3 . Each power supply device 8 receives the request via the communication device 84 and sends the device status information to the communication device 3 according to the request. The control device 5 obtains the device state information via the communication device 3, and stores the obtained device state information in the memory unit 5C.

Next, the control device 5 performs control determination for determining the device state of each power supply device 8 based on the acquired device state information (step S22). In step S22, the control device 5 refers to the device state information, and determines whether each power supply device 8 is in an abnormal state, in a warning state, or in a normal state.

When all the power supply devices 8 are not in an abnormal state and are not in a warning state (NO in step S23 and NO in step S24 ), the series of processes in the current cycle ends, and the second cycle, which is shorter than the first cycle, ends. cycle (for example, 1 second), it shifts to the process of the above-mentioned step S21 in the next cycle. In other words, the device status information is transmitted from the communication device 84 to the control device 5 in the second cycle shorter than the first cycle when the power supply device 8 is normal.

On the other hand, when at least one power supply device 8 is in an abnormal state (in the case of YES in step S23 ), the temperature and power of the power supply device 8 in the abnormal state are checked (step S25 ). In step S25 , specifically, a request for temperature and power information is made from the control device 5 to the power supply device 8 in an abnormal state via the communication device 3 . The power supply device 8 in the abnormal state receives the request via the communication device 84 and sends the temperature and power information to the communication device 3 according to the request. The control device 5 obtains the temperature and power information through the communication device 3, and stores the obtained temperature and power information in the memory unit 5C.

Next, by the control device 5, the display of the display unit 5A is updated to facilitate the display of the acquired temperature and power information, and the route is blocked in the section corresponding to the power supply device 8 determined to be in an abnormal state, that is, the abnormal section on the track 4 (step S26). In the route lock of step S26, the transport cart 6 is prohibited from entering the abnormal section of the rail 4, and the transport cart 6 existing in the abnormal section is withdrawn from the abnormal section. For example, in the route lock of step S26, when some commands (for example, a travel command or a transfer command) are allocated to the transport vehicle 6, a command not to pass through the abnormal section is allocated. For example, in the route lock of step S26, a command to travel outside the abnormal section is assigned to the transport cart 6 existing in the abnormal section. In addition, in step S26 , the power supply device 8 determined to be in an abnormal state is stopped by the control device 5 .

Next, the control device 5 determines whether or not the abnormal state of the power supply device 8 is a temperature abnormality based on the device state information of the power supply device 8 in the abnormal state (step S27 ). When the abnormal state of the power supply device 8 is a temperature abnormality (in the case of YES in step S27 ), the control device 5 acquires a temperature distribution image related to the temperature distribution causing the temperature abnormality (step S28 ).

In step S28 , specifically, a request for temperature and power information is made from the control device 5 to the power supply device 8 in an abnormal state via the communication device 3 . The power supply device 8 in the abnormal state receives the request via the communication device 84 and sends the temperature and power information to the communication device 3 according to the request. The control device 5 obtains the temperature power information through the communication device 3, and obtains the temperature distribution which becomes the abnormal temperature from the temperature data of the temperature power information. The control device 5 generates and acquires a temperature distribution image using, for example, a known method based on the acquired temperature distribution. In other words, in step S28, when the control device 5 determines that the state of the power supply device 8 is an abnormal state, and when the abnormal state is a temperature abnormality, the communication device 84 transmits information about the power supply device determined to be in the abnormal state. 8 Information on temperature distribution (temperature power information). Next, in order to facilitate the display of the acquired temperature distribution image, the display of the display unit 5A is updated by the control device 5, and the acquired temperature distribution image is stored in the memory unit 5C (step S29).

On the other hand, when all the power supply devices 8 are not in an abnormal state and at least one of the power supply devices 8 is in a warning state (in the case of NO in step S23 and YES in step S24 ), the power supply device in the warning state is checked. 8 temperature and power (step S30). In step S30 , specifically, a request for temperature and power information is made from the control device 5 to the power supply device 8 in the warning state via the communication device 3 . The power supply device 8 in the warning state receives the request via the communication device 84 and sends the temperature and power information to the communication device 3 according to the request. The control device 5 obtains the temperature and power information through the communication device 3, and stores the obtained temperature and power information in the memory unit 5C.

Next, the control device 5 updates the display of the display unit 5A to facilitate the display of the acquired temperature and power information, and the transport trolley exists in the section corresponding to the power supply device 8 determined to be in the warning state, that is, the transport trolley in the warning section on the rail 4 The acceleration of 6 is limited (step S31). As an example, in the acceleration limitation in step S31, the highest acceleration of the command assigned to the transport vehicle 6 existing in the warning section is set to be equal to or less than a preset set acceleration.

In the case of NO in step S27, after step S29 or after step S31, the series of processing in the current cycle ends, and the process shifts to the above-described processing in step S21 in the next cycle. In addition, the abnormality monitoring flow is set to a lower priority than the above-mentioned regular monitoring flow and manual image acquisition flow. Therefore, when each process of either the regular monitoring flow or the manual image acquisition flow is being executed, it is not Execute each process of the abnormality monitoring flow.

As described above, in the transport trolley system 1, the power supply device 8 is installed in each of the plurality of sections formed by dividing the rails 4, and the state of each power supply device 8 is monitored by the non-contact temperature sensor 81 and the current sensor 82. The monitoring results of 8 are controlled by the control device 5 to control the conveyance trolley 6 . Thereby, when a malfunction occurs in the power supply device 8 , the control device 5 can execute a process that is not a shutdown of the entire system but a local shutdown. Therefore, the system shutdown of the transport cart system 1 can be prevented.

In the conveyance cart system 1 , the control device 5 determines whether or not the states of the plurality of power supply devices 8 are abnormal based on the monitoring results of the power supply devices 8 . The control device 5 prohibits the transport trolley 6 from entering the abnormal section corresponding to the power supply device 8 determined to be in an abnormal state, and causes the transport trolley 6 existing in the abnormal section to retreat from the abnormal section. In this way, it is possible to effectively suppress the situation that the bad influence caused by the failure of the power supply device 8 spreads to the whole system. In the transport cart system 1, the work of reducing the transport capacity can be continued.

In the transport cart system 1, the control device 5 stops the power supply device 8 determined to be in an abnormal state. In this way, it is possible to effectively suppress the situation that the bad influence caused by the failure of the power supply device 8 spreads to the whole system. It is possible to suppress the development of the malfunction of the power supply device 8 . It is easy to restore the power supply device 8 early from a malfunction.

In the transport cart system 1, the control device 5 determines whether or not the states of the plurality of power supply devices 8 are in the warning state based on the monitoring results of the power supply devices 8, and transports the transportation in the warning section corresponding to the power supply device 8 determined to be in the warning state. The acceleration of the cart 6 is limited. In this way, it is possible to effectively suppress the situation that the bad influence caused by the failure of the power supply device 8 spreads to the whole system. In the transport cart system 1, the work of reducing the transport capacity can be continued.

In the transport cart system 1, in step S28, when the control device 5 determines that the state of the power supply device 8 is an abnormal state, and when the abnormal state is a temperature abnormality, the communication device 84 sends a transmission to the control device 5. There is temperature power information on the temperature distribution in the power supply device 8 determined to be in an abnormal state. Thereby, in the control apparatus 5, the temperature distribution which becomes the temperature abnormality of the power supply apparatus 8 can be displayed on the display part 5A as a temperature distribution image. The user can easily grasp the temperature distribution of the power supply device 8 causing the temperature abnormality in the control device 5 .

In the transport cart system 1, the temperature and power information is transmitted from the communication device 84 to the control device 5 in the first cycle. The device status information is sent from the communication device 84 to the control device 5 in a second cycle shorter than the first cycle when the power supply device 8 is normal. Therefore, when the temperature power information and the device status information are periodically sent from the power supply device 8 to the control device 5, the communication period of the temperature power information whose data capacity is larger than that of the device status information will be longer than the communication period of the device status information. long. Therefore, the traffic of the communication device 84 can be suppressed. In addition, the communication load can be suppressed.

In the transport cart system 1, desired temperature power information and device status information can be easily displayed by the display unit 5A. In addition, the display of the display unit 5A can be easily set and operated. In addition, when the power supply device 8 is in an abnormal state by the user's operation, the temperature distribution image of the temperature distribution related to the temperature abnormality can be displayed on the display unit 5A.

Although the single embodiment has been described above, one aspect of the present invention is not limited to the above-described embodiment, and various modifications can be made without departing from the gist of the invention.

In the above-described embodiment, the monitoring device is not limited to the non-contact temperature sensor 81 and the current sensor 82 , and may be other sensors or the like that can monitor the state of the power supply device 8 . In the above-described embodiment, the power supply device 8 may include only one of the non-contact temperature sensor 81 and the current sensor 82 . In the above-described embodiment, the area in which the temperature is measured by the non-contact temperature sensor 81 in the power supply device 8 is not limited, and various areas may be used. In the above-described embodiment, the measurement point at which the current sensor 82 in the power supply device 8 measures the current is not limited, and various measurement points may be used.

In the above embodiment, the first cycle when the communication device 84 sends the temperature and power information and the second cycle when the communication device 84 sends the device status information are not particularly limited, as long as the second cycle is shorter than the first cycle . The first cycle and the second cycle may be fixed values or fluctuating values that fluctuate depending on the situation. In the above-described embodiment, when the control device 5 determines that the power supply device 8 is in an abnormal state or a warning state, it may notify the power supply device 8 to call attention (for example, a call to attention on the display unit 5A).

In the above-described embodiment, one example of the power supply devices 8 provided with two is shown and described, but the number of the power supply devices 8 is not limited, and the number of the power supply devices 8 may be plural. In the above-described embodiment, a plurality of units composed of a plurality of power supply devices 8 and control devices 5 may be provided. In this case, a higher-level control device that includes a plurality of control devices 5 may be provided. The above-described embodiment may include a data server that manages data of the entire system. The above-described embodiment may include an overall control device that controls the entire system. In the above-described embodiments, wireless communication may be used for part or all of communication, or wired communication may be used. In the above-described embodiment, for example, the LAN line of the facility in which the conveyance cart system 1 is installed may be used for a part or all of the communication.

In the above-described embodiment, the following are executed: stop of the power supply device 8 in an abnormal state; prohibition of the transport trolley 6 from entering the abnormal section; evacuation of the transport trolley 6 existing in the abnormal section from the abnormal section; and transport trolley existing in the warning section. 6 acceleration limits, but only need to implement at least any of these.

The respective configurations of the above-described embodiments and modifications are not limited to the above-described materials and shapes, and various materials and shapes can be applied. Each configuration of the above-described embodiment or modification can be arbitrarily applied to each configuration of other embodiment or modification. A part of each structure of the above-mentioned embodiment or modification can be suitably omitted in the range which does not deviate from the summary of one aspect of this invention.

1: Handling trolley system 4: Track 4X: 1st interval (interval) 4Y: Second section (section) 5: Control device 6: Handling trolley 8, 8X, 8Y: Power supply unit 81: Non-contact temperature sensor (monitoring device) 82: Current sensor (monitoring device) 84: Communication device

[ Fig. 1 ] is a schematic diagram showing a transport cart system according to an embodiment. [ Fig. 2] Fig. 2 is a schematic front view of the transport vehicle shown in Fig. 1 as viewed from the traveling direction. [ Fig. 3] Fig. 3 is a block diagram showing the configuration of the power supply device of Fig. 1 . [ Fig. 4] Fig. 4 is a diagram showing an example of a display displayed on a display unit of the control device in Fig. 1 . [Fig. 5(a)] is a flowchart showing a flow of periodic monitoring of the conveyance cart system of Fig. 1 . [ Fig. 5(b)] is a flowchart showing a flow of manual image acquisition in the conveyance cart system of Fig. 1 . [ Fig. 6] Fig. 6 is a flowchart showing a flow of abnormality monitoring in the transport vehicle system of Fig. 1 .

1: Handling trolley system

3: Communication device

4: Track

4X: 1st interval (interval)

4Y: Second section (section)

5: Control device

5A: Display part

5B: Input section

5C: Memory Department

6: Handling trolley

8, 8X, 8Y: Power supply unit

9: Loading part

40E: Power Supply Department

40EX: 1st Power Supply Department

40EY: 2nd power supply department

Claims (6)

A handling trolley system is provided with: Carry the trolley and walk along the track; a control device for controlling the aforementioned transport trolley; and A power supply device is provided in each of the plurality of sections formed by distinguishing the rails, Each of the plurality of power supply devices includes: a monitoring device for monitoring the state of the power supply device; and a communication device for sending a monitoring result generated by the monitoring device to the control device, The control device controls the transfer cart based on the monitoring result. The handling trolley system of claim 1, wherein, the aforementioned control device, Based on the monitoring results, it is determined whether or not the states of the plurality of power supply devices are abnormal states, The transport trolley is prohibited from entering the section corresponding to the power supply device determined to be in the abnormal state, and the transport trolley existing in the section is caused to retreat from the section. The handling trolley system of claim 2, wherein, The control device further controls the power supply device to stop the power supply device determined to be in the abnormal state. A handling trolley system as claimed in claim 2 or 3, wherein, the aforementioned control device, Based on the monitoring results, it is determined whether the states of the plurality of power supply devices are in a warning state with a degree of abnormality lower than that of the abnormal state, The acceleration of the transport cart existing in the section corresponding to the power supply device determined to be in the warning state is reduced. A handling trolley system as claimed in claim 2 or 3, wherein, When it is determined by the control device that the state of the power supply device is an abnormal state, and the abnormal state is a temperature abnormality, the communication device transmits information about the power supply device in the abnormal state determined to the abnormal state from the communication device to the control device. Information on temperature distribution. The handling trolley system of claim 1, wherein, The monitoring result includes: first information including at least one of temperature data and power data of the power supply device; and second information about whether the state of the power supply device is an abnormal state, The first information is sent from the communication device to the control device in the first cycle, The second information is transmitted from the communication device to the control device in a second cycle shorter than the first cycle when the power supply device is normal.

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